CN101592775A - Zoom lens and image pick up equipment - Google Patents

Zoom lens and image pick up equipment Download PDF

Info

Publication number
CN101592775A
CN101592775A CNA2009102028195A CN200910202819A CN101592775A CN 101592775 A CN101592775 A CN 101592775A CN A2009102028195 A CNA2009102028195 A CN A2009102028195A CN 200910202819 A CN200910202819 A CN 200910202819A CN 101592775 A CN101592775 A CN 101592775A
Authority
CN
China
Prior art keywords
lens
lens combination
combination
refractive power
zoom
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CNA2009102028195A
Other languages
Chinese (zh)
Other versions
CN101592775B (en
Inventor
金井真实
细井正晴
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Sony Corp
Original Assignee
Sony Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sony Corp filed Critical Sony Corp
Publication of CN101592775A publication Critical patent/CN101592775A/en
Application granted granted Critical
Publication of CN101592775B publication Critical patent/CN101592775B/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B15/00Optical objectives with means for varying the magnification
    • G02B15/14Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective
    • G02B15/16Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective with interdependent non-linearly related movements between one lens or lens group, and another lens or lens group
    • G02B15/177Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective with interdependent non-linearly related movements between one lens or lens group, and another lens or lens group having a negative front lens or group of lenses
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B15/00Optical objectives with means for varying the magnification
    • G02B15/14Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective
    • G02B15/143Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having three groups only
    • G02B15/1435Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having three groups only the first group being negative
    • G02B15/143507Optical objectives with means for varying the magnification by axial movement of one or more lenses or groups of lenses relative to the image plane for continuously varying the equivalent focal length of the objective having three groups only the first group being negative arranged -++

Landscapes

  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Nonlinear Science (AREA)
  • Lenses (AREA)
  • Studio Devices (AREA)

Abstract

Zoom lens and image pick up equipment are provided.Described zoom lens comprise first to the 3rd concave, convex, convex lens group.Second lens combination comprises first to the 4th convex lens, concavees lens, concavees lens, convex lens.Described third and fourth lens of described second lens combination are engaged with each other to be used as cemented lens.Described zoom lens are configured to and satisfy following conditional expression (1) and (2): (1)-0.5<f2/f2R<0, (2) 0.09<L2/LT<0.19, wherein f2 is the focal length of second lens combination, f2R is the combined focal length of cemented lens that comprises third and fourth lens of second lens combination, L2 is the total length about the optical axis of second lens combination, and LT is at the total optical path of end of dolly-out,ing dolly-back.

Description

Zoom lens and image pick up equipment
Technical field
The present invention relates to zoom lens and image pick up equipment.Specifically, the technical field that the present invention relates to be suitable for the zoom lens of the imaging optical system in the digital input-output apparatus and comprise the image pick up equipment of these zoom lens.
Background technology
In recent years, the image pick up equipment such as the compactness of Digital Video or digital camera and so on catches on.In this image pick up equipment, the lens performance that require to increase zoom lens is with the increase of the number of pixels that satisfies image pickup device.And, wish that the size of image pick up equipment reduces.Because this, requirement reduces the total length of zoom lens.Further, wish to promote the manufacturing of image pick up equipment to boost productivity by the sensitivity that reduces excentricity.
The zoom lens of installing on the image pick up equipment of for example digital camera and so on comprise various types of zoom lens.One of this zoom lens that installation and size reduce on image pick up equipment are the zoom lens that comprise three lens combination, these three lens combination comprise with from the object side to image side first lens combination with negative refractive power (refractive power) that is disposed in order, have second lens combination of positive refractive power and have the 3rd lens combination (for example, referring to Japanese unexamined patent open No.2002-244043,2004-191599 and 2007-212777) of positive refractive power.
Openly comprise the zoom lens of second lens combination among the open No.2002-244043 of Japanese unexamined patent, described second lens combination comprises two bonding (cemented) lens with positive refractive power.
Openly comprise the zoom lens of second lens combination among the open No.2004-191599 of Japanese unexamined patent, described second lens combination comprises two cemented lenses.Second lens combination comprises five lens of total, that is, and and three convex lens (positive lens) and two concavees lens (negative lens).
The zoom lens that openly comprise second lens combination among the open No.2007-212777 of Japanese unexamined patent, described second lens combination comprise the single lens with positive refractive power and have negative refractive power and comprise the cemented lens of two lens.
Summary of the invention
In the disclosed zoom lens, the distance between two cemented lenses of second lens combination is very big in the open No.2002-244043 of Japanese unexamined patent.When with zoom lens applications expandable in comprising/during the folding image pick up equipment of reducible lens barrel, specifically, total optical path may become big when lens barrel shrinks.This may be the bottleneck that size reduces.
And, in open No.2002-244043 of Japanese unexamined patent and 2004-191599 disclosed zoom lens each all comprise second lens combination, it is included in the cemented lens with positive refractive power as side.The basic point of second lens combination (principal point) may be positioned at the position near the picture side.It is big that total optical path may become.This may be the bottleneck that size reduces.
The open disclosed zoom lens of No.2004-191599 of Japanese unexamined patent comprise second lens combination with five lens.The number of lens is very big, and therefore, it is big that total optical path may become.Cun requirement that reduces of this discontented full size.Specifically, therein with zoom lens applications under the situation of folding image pick up equipment, total optical path may become big when lens barrel shrinks.This may be the bottleneck that size reduces.
Disclosed zoom lens promote reducing of size among the open No.2007-212777 of Japanese unexamined patent, so that second lens combination comprises three lens.Yet aberration (aberration) correcting value of distributing to the lens of second lens combination may increase.The sensitivity of the excentricity of second lens combination may increase, and therefore, it is difficult that manufacturing may become.
Therefore, expectation provides zoom lens and the image pick up equipment that solves above-mentioned bottleneck, promotes reducing of size by reducing total optical path, and promotes throughput rate to increase by the sensitivity that reduces excentricity, and high optical property is provided simultaneously.
Zoom lens comprise with from the object side to image side first lens combination order, that have negative refractive power, have second lens combination of positive refractive power and have the 3rd lens combination of positive refractive power according to an embodiment of the invention.During convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move first lens combination with optical axis direction, and second lens combination is moved to the thing side, so that the space length between first and second lens combination (airdistance) reduces and make the space length between the second and the 3rd lens combination increase.Second lens combination comprises with from the object side to image side first lens order, that have positive refractive power, has second lens of negative refractive power, has the 3rd lens of negative refractive power and has the 4th lens of positive refractive power.Third and fourth lens of second lens combination are engaged with each other to be used as cemented lens.Zoom lens are configured to and satisfy following conditional expression (1) and (2):
(1)-0.5<f2/f2R<0 and
(2)0.09<L2/LT<0.19,
Wherein f2 is the focal length of second lens combination, and f2R is the combined focal length of cemented lens that comprises third and fourth lens of second lens combination, and L2 is the total length about the optical axis of second lens combination, and LT is at the total optical path of end of dolly-out,ing dolly-back.
In the zoom lens of this embodiment, second lens combination comprises four lens with cemented lens.And, in preset range, determine to comprise the focal length of cemented lens of third and fourth lens of second lens combination and the total optical path of second lens combination.
Therefore, by the zoom lens of this embodiment, can reduce total optical path, and can promote reducing of size thus.And, can increase throughput rate by the sensitivity that reduces excentricity, high optical property is provided simultaneously.
Preferably, zoom lens are configured to and satisfy following conditional expression (3):
(3)v24-v23>20,
Wherein v24 is the Abbe number (Abbe number) of the 4th lens of second lens combination, and v23 is the Abbe number of the 3rd lens of second lens combination.
The expression formula because satisfy condition (3) is so can reduce the appearance of aberration.
In addition, in the zoom lens according to this embodiment, the picture side surface of the 4th lens of second lens combination is preferably aspheric.
Because the 4th lens of second lens combination is aspheric surface as side surface, so can reduce the appearance of comatic aberration (coma) and astigmatism (astigmatism).
Image pick up equipment according to another embodiment of the present invention comprises zoom lens; With will be converted to the image pickup device of electric signal by the optical imagery that zoom lens form.Zoom lens comprise first lens combination with negative refractive power, have second lens combination of positive refractive power and have the 3rd lens combination of positive refractive power with from the object side to image side order.Zoom to from wide-angle side dolly-out, dolly-back the end during, move first lens combination with optical axis direction, and second lens combination is moved to the thing side, so that the space length between first and second lens combination reduces and make the space length between the second and the 3rd lens combination increase.Second lens combination comprises first lens, second lens with negative refractive power with positive refractive power, has the 3rd lens of negative refractive power and has the 4th lens of positive refractive power with from the object side to image side order.Third and fourth lens of second lens combination are engaged with each other to be used as cemented lens.Zoom lens are configured to and satisfy following conditional expression (1) and (2):
(1)-0.5<f2/f2R<0 and
(2)0.09<L2/LT<0.19,
Wherein f2 is the focal length of second lens combination, and f2R is the combined focal length of cemented lens that comprises third and fourth lens of second lens combination, and L2 is the total length about the optical axis of second lens combination, and LT is at the total optical path of end of dolly-out,ing dolly-back.
In the image pick up equipment of this embodiment, second lens combination of zoom lens comprises four lens with cemented lens.And, in preset range, determine to comprise the total optical path of second lens combination of the focal length of cemented lens of third and fourth lens of second lens combination of zoom lens and zoom lens.
Therefore, provide zoom lens in the image pick up equipment by this embodiment, can reduce total optical path, and can promote that thus size reduces.And, can increase throughput rate by the sensitivity that reduces excentricity, high optical property is provided simultaneously.
Description of drawings
Fig. 1 diagram is according to the lens configuration of the zoom lens of first embodiment, and it is a preferred embodiment of realizing image pick up equipment and zoom lens with Fig. 2 to 17;
Fig. 2 illustrates the aberration figure that special value is applied to the numerical example of first embodiment with Fig. 3 and 4, and illustrates spherical aberration, astigmatism and distortion in wide-angle side;
Fig. 3 is shown in spherical aberration, astigmatism and the distortion of middle focal length;
Fig. 4 is shown in spherical aberration, astigmatism and the distortion of the end of dolly-out,ing dolly-back;
Fig. 5 diagram is according to the lens configuration of the zoom lens of second embodiment of the invention;
Fig. 6 illustrates the aberration figure that special value is applied to the numerical example of second embodiment with Fig. 7 and 8, and illustrates spherical aberration, astigmatism and distortion in wide-angle side;
Fig. 7 is shown in spherical aberration, astigmatism and the distortion of middle focal length;
Fig. 8 is shown in spherical aberration, astigmatism and the distortion of the end of dolly-out,ing dolly-back;
Fig. 9 diagram is according to the lens configuration of the zoom lens of third embodiment of the invention;
Figure 10 illustrates the aberration figure that special value is applied to the numerical example of the 3rd embodiment with Figure 11 and 12, and illustrates spherical aberration, astigmatism and distortion in wide-angle side;
Figure 11 is shown in spherical aberration, astigmatism and the distortion of middle focal length;
Figure 12 is shown in spherical aberration, astigmatism and the distortion of the end of dolly-out,ing dolly-back;
Figure 13 diagram is according to the lens configuration of the zoom lens of fourth embodiment of the invention;
Figure 14 illustrates the aberration figure that special value is applied to the numerical example of the 4th embodiment with Figure 15 and 16, and illustrates spherical aberration, astigmatism and distortion in wide-angle side;
Figure 15 is shown in spherical aberration, astigmatism and the distortion of middle focal length;
Figure 16 is shown in spherical aberration, astigmatism and the distortion of the end of dolly-out,ing dolly-back; With
Figure 17 shows the block diagram according to the image pick up equipment of embodiment.
Embodiment
Following description is used to realize the preferred embodiment of zoom lens and image pick up equipment.
At first, zoom lens are according to an embodiment of the invention described.
Comprise with from the object side to image side first lens combination order, that have negative refractive power, have second lens combination of positive refractive power and have the 3rd lens combination of positive refractive power according to the zoom lens of the embodiment of the invention.Between wide-angle side and the end of dolly-out,ing dolly-back (telephoto end), moving first, second and the 3rd lens combination during the image zoom with optical axis direction.
For example, zoom to from wide-angle side dolly-out, dolly-back the end during, move first lens combination with optical axis direction, second lens combination is moved to the thing side, and the 3rd lens combination is moved to the picture side, so that the space length between first and second lens combination reduces and make the space length between the second and the 3rd lens combination increase.
In the zoom lens of this embodiment, second lens combination comprise with from the object side to image side first lens order, that have positive refractive power, have negative refractive power second lens, have the 3rd lens of negative refractive power and have the 4th lens of positive refractive power.Engage third and fourth lens, thus serve as cemented lens.
In the zoom lens of this embodiment, second lens combination comprises four lens, and provides cemented lens by third and fourth lens.That is to say that the number of lens is very little, and two lens are as cemented lens.Therefore, can reduce total optical path.
Zoom lens are configured to and satisfy following conditional expression (1) and (2):
(1)-0.5<f2/f2R<0 and
(2)0.09<L2/LT<0.19,
Wherein f2 is the focal length of second lens combination, and f2R is the combined focal length of cemented lens that comprises third and fourth lens of second lens combination, and L2 is the total length on the optical axis of second lens combination, and LT is at the total optical path of end of dolly-out,ing dolly-back.
Conditional expression (1) is determined the focal length and the ratio of the 3rd lens with negative refractive power that comprise second lens combination with the focal length of the cemented lens of the 4th lens with positive refractive power of second lens combination.
If the value of conditional expression (1) is higher than the upper limit, then the position of the basic point of second lens becomes too near the picture side.It is big that total optical path may become.This may be the bottleneck that size reduces.
On the contrary, if the value of conditional expression (1) is lower than lower limit, comprise that then the refractive power variable of cemented lens of the 3rd lens of second lens combination and the 4th lens is too much.Therefore, the combination refractive power of first and second lens of second lens combination also becomes big.Therefore, the sensitivity of the excentricity of the cemented lens of second lens combination and first and second lens becomes excessive.It is difficult that manufacturing may become.
If the value of conditional expression (1) is lower than lower limit, specifically, the distance between exit pupil position (exit pupilposition) and the plane of delineation diminishes in wide-angle side, and becomes greatly from the incident angle of Axial Bundle (off-axis lightbeam) about the plane of delineation.Therefore, increase shade.
Conditional expression (2) is determined the total length of second lens combination.
For reducing the total optical path of whole zoom-lens system when being compressed (contraction), expectation reduces the total length of second lens combination.Yet if the value of conditional expression (2) is lower than lower limit, the total length of second lens combination becomes too small, and the sensitivity of the excentricity error of second lens combination uprises.Therefore, must carry out assembling with very high precision.
On the contrary, if the value of conditional expression (2) is higher than the upper limit, then the total length of second lens combination becomes excessive, and is difficult to promote reducing of total optical path under the compressive state.
Therefore, when zoom lens satisfy condition expression formula (1) and (2), can reduce total optical path, and can promote reducing of size thus.And, can increase throughput rate by the sensitivity that reduces excentricity, high optical property is provided simultaneously.
In zoom lens, preferably satisfy following conditional expression (3) according to the embodiment of the invention:
(3)v24-v23>20,
Wherein v24 is the Abbe number of the 4th lens of second lens combination, and v23 is the Abbe number of the 3rd lens of second lens combination.
Conditional expression (3) is determined the relation between the Abbe number of the Abbe number of the 3rd lens (concavees lens) of cemented lens of second lens combination and the 4th lens (convex lens).
If should value outside by the defined scope of conditional expression (3), then the difference of Abbe number becomes too small.Correcting chromatic aberration, and optical property deficiently reduces.
When zoom lens satisfy condition expression formula (3), correcting chromatic aberration suitably, and can increase optical property.
In this embodiment, the numerical range of conditional expression (3) preferably be set to following conditional expression (3) ' scope:
(3)′v24-v23>25。
Depend on selected material, the Abbe number of third and fourth lens of second lens combination can be set to by the desirable value in the scope of conditional expression (3) or (3) ' definition.
In addition, by the zoom lens according to the embodiment of the invention, the picture side surface of the 4th lens of second lens combination is preferably aspheric.
When the 4th lens of second lens combination be aspheric surface as side surface the time, can suitably proofread and correct comatic aberration and astigmatism.
In these zoom lens, when the part of one of first to the 3rd lens combination or lens combination so that the direction perpendicular to optical axis moves (displacement) in fact, image can displacement.By with in fact perpendicular to the direction mobile lens group of optical axis or the part of lens combination, with drive system by the fuzzy detection system of detected image, displacement lens combination are provided with will be applied to the combination of the control system of drive system based on the displacement of the output of detection system, zoom lens can also be used as the image stabilization optical system.Specifically, in zoom lens, with in fact perpendicular to whole second lens combination of the direction displacement of optical axis according to the embodiment of the invention.Therefore, can change the displacement diagram picture with little aberration.
In the zoom lens according to the embodiment of the invention, expectation is carried out focusing by move the first or the 3rd lens combination with optical axis direction.Specifically, when the 3rd lens combination when acting on the lens combination of focusing, prevent that easily the 3rd lens combination from disturbing the drive system of the drive controlling of carrying out shutter unit or aperture unit (iris unit) or the image stabilization drive system of displacement lens combination.Therefore, can promote that size reduces.
Next, with table the specific embodiment of zoom lens and the numerical example that special value is applied to embodiment are described with reference to the accompanying drawings.
Be used to show with the implication of the Reference numeral of instructions as follows.
" Si " expression is the surface number on i surface of counting from the object side to image side, the radius-of-curvature on i surface of " Ri " expression, " Di " is illustrated in the axial plane distance between i surface and (i+1) individual surface, the d line of the material of i lens of " Ni " expression (wavelength: the refractive index of 587.6nm) locating, and " vi " is the Abbe number at the d line place of the material of i lens.About radius-of-curvature, " ASP " represents non-spherical surface, and " INF " expression flat surfaces.
Some lens that is used for each numerical example have aspheric lens surface.Aspheric surface configuration is defined by following equation 1:
x = cy 2 1 + { 1 - ( 1 + K ) c 2 y 2 } + Σ A i · y i . . . Equation 1
Wherein " x " is in the distance of optical axis direction apart from the summit of lens surface, " y " is perpendicular to the height of the direction of optical axis, " c " is the paraxonic curvature (inverse of radius-of-curvature) in lens apex, " K " is conic constant (conic constant), and " Ai " is i rank asphericity coefficients.
Fig. 1 diagram is according to the lens configuration of the zoom lens 1 of first embodiment of the invention.
As shown in Figure 1, the zoom lens 1 of first embodiment comprise eight lens.
Zoom lens 1 comprise with from the object side to image side first lens combination GR1 order, that have negative refractive power, have the second lens combination GR2 of positive refractive power and have the 3rd lens combination GR3 of positive refractive power.
In zoom lens 1, during the image zoom wide-angle side and dolly-out, dolly-back the end between move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction.For example, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 reduces and make the space length between the second lens combination GR2 and the 3rd lens combination GR3 increase.On the contrary, during holding the image zoom of wide-angle side from dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 increases and makes the space length between the second lens combination GR2 and the 3rd lens combination GR3 reduce.
The first lens combination GR1 with comprise from the object side to image side order, its convex surface in the face of concavo-convex (meniscus) first lens G11 of thing side, its convex surface with negative refractive power in the face of concavo-convex compound (meniscus compound) aspheric surface second lens G12 with negative refractive power of thing side and its convex surface concavo-convex the 3rd lens G13 with positive refractive power in the face of the thing side.The second lens G12's is aspheric surface as side surface.
The second lens combination GR2 comprises concavo-convex the 4th lens G24 with positive refractive power that faces the thing side in the face of concavo-convex the 3rd lens G23 with negative refractive power and its convex surface of thing side with biconvex first lens G21 order, that have positive refractive power from the object side to image side, the biconvex second lens G22 with negative refractive power, its convex surface.The thing side surface of the first lens G21 and the 4th lens G24's is aspheric surface as side surface.
The first lens G21 and the second lens G22 form the cemented lens with composition surface R10, join the first lens G21 thing side concave surface of the second lens G22 to as the side convex surface at this composition surface R10.This convex surface has identical radius-of-curvature with concave surface.
The 3rd lens G23 and the 4th lens G24 form the cemented lens with composition surface R13, join the 3rd lens G23 the thing side convex surface of the 4th lens G24 to as the side concave surface at this composition surface R13.This concave surface has identical radius-of-curvature with convex surface.
The 3rd lens combination GR3 comprises the biconvex lens G31 with positive refractive power.Two surfaces of lens G31 all are aspheric surfaces.
Between the first lens combination GR1 and the second lens combination GR2, arrange aperture diaphragm (aperture stop) S (aperture diaphragm surface R8).
Between the 3rd lens combination GR3 and plane of delineation IMG, arrange wave filter FL.
Table 1 shows special value and is applied to lens data according to the numerical example 1 of the zoom lens 1 of first embodiment.
[table 1]
Si Ri Di Ni vi
1 33.205 1.000 1.88300 40.8
2 10.500 4.241
3 72.761 0.900 1.61800 63.4
4 26.760 0.100 1.53420 41.7
5 21.482(ASP) 1.533
6 20.743 1.927 1.84666 23.8
7 60.486 D7
8 Aperture diaphragm 0.500
9 9.668(ASP) 3.900 1.85135 40.1
10 -12.769 0.600 1.64769 33.8
11 12.583 0.672
12 9.731 0.590 2.00069 25.5
13 4.830 2.738 1.69350 53.2
14 9.520(ASP) D14
15 35.506(ASP) 3.400 1.61881 63.9
16 -32.138(ASP) D16
17 INF 1.800 1.51872 64.2
18 INF
In zoom lens 1, the picture side surface (R16) of the thing side surface (R15) of the picture side surface (R14) of the thing side surface (R9) of the picture side surface (R5) of the second lens G12 of the first lens combination GR1, the first lens G21 of the second lens combination GR2, the 4th lens G24 of the second lens combination GR2, the lens G31 of the 3rd lens combination GR3 and the lens G31 of the 3rd lens combination GR3 is an aspheric surface.Table 2 shows asphericity coefficient A4, A6, A8 and A10 and the conic constant K on the 4th, the 6th, the 8th and the 10th rank of the non-spherical surface of numerical example 1.
At table 2 that shows asphericity coefficient and table described below, " E-i " represents the index based on 10, that is, and and " 10 -i".For example, " 0.12345E-05 " expression " 0.12345 * 10 -5".
[table 2]
Si K A4 A6 A8 A10
5 0.00000E+00 -7.04741E-05 -4.13183E-08 -3.66756E-09 -1.02671E-11
9 0.00000E+00 -9.48320E-05 -7.72767E-07 -4.82074E-08 8.12567E-10
14 0.00000E+00 2.40216E-04 8.28194E-06 -7.48375E-07 1.44741E-08
15 0.00000E+00 7.63309E-05 -1.02535E-06 1.13956E-08 -4.62808E-11
16 0.00000E+00 2.10714E-04 -2.70474E-06 2.87685E-08 -9.99317E-11
In zoom lens 1, wide-angle side and dolly-out, dolly-back the end between image zoom during, surface distance D14 between the surface distance D7 between the first lens combination GR1 and the second lens combination GR2, the second lens combination GR2 and the 3rd lens combination GR3 and the surface distance D16 between the 3rd lens combination GR3 and the wave filter FL are variablees.Table 3 with f-number (F-numbers) Fno and half angle of view ω show in numerical example 1 in wide-angle side (focal distance f=9.90), the variable distance of the surface distance of middle focal length (focal distance f=16.3) and the end of dolly-out,ing dolly-back (focal distance f=28.5).
[table 3]
Fno 2.90 3.83 5.58
f 9.90 16.3 28.5
ω 40.3 26.1 15.4
D7 19.058 8.932 2.000
D14 7.154 15.277 28.894
D16 5.000 4.212 3.041
Fig. 2 to 4 shows the aberration figure at infinity according to numerical example 1.Fig. 2 is shown in the aberration figure of wide-angle side (focal distance f=9.90).Fig. 3 is shown in the aberration figure of middle focal length (focal distance f=16.3).Fig. 4 is shown in the aberration figure of the end of dolly-out,ing dolly-back (focal distance f=28.5).
In the spherical aberration figure of Fig. 2 to 4, solid line is illustrated in the d line, and (wavelength: value 587.6nm), dotted line are illustrated in the value of c line (wavelength 656.3nm), and dot-and-dash line is illustrated in g line (wavelength: value 435.8nm).In the astigmatism aberration figure of Fig. 2 to 4, solid line is illustrated in the value of vowing shape (sagittal) plane of delineation, and dotted line is illustrated in the value of meridian (meridional) plane of delineation.
In aberration figure, find the imaging performance of in numerical example 1, suitably having proofreaied and correct aberration and providing.
Fig. 5 diagram is according to the lens configuration of the zoom lens 2 of second embodiment of the invention.
As shown in Figure 5, the zoom lens 2 of second embodiment comprise eight lens.
Zoom lens 2 comprise with from the object side to image side first lens combination GR1 order, that have negative refractive power, have the second lens combination GR2 of positive refractive power and have the 3rd lens combination GR3 of positive refractive power.
In zoom lens 2, during the image zoom wide-angle side and dolly-out, dolly-back the end between move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction.For example, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 reduces and make the space length between the second lens combination GR2 and the 3rd lens combination GR3 increase.On the contrary, during holding the image zoom of wide-angle side from dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 increases and makes the space length between the second lens combination GR2 and the 3rd lens combination GR3 reduce.
The first lens combination GR1 comprise with from the object side to image side order, its convex surface in the face of the concavo-convex compound aspheric surface first lens G11 with negative refractive power of thing side, its convex surface in the face of the concavo-convex second lens G12 with negative refractive power of thing side and its convex surface concavo-convex the 3rd lens G13 with positive refractive power in the face of the thing side.The second lens G12's is aspheric surface as side surface.
The second lens combination GR2 comprises concavo-convex the 4th lens G24 with positive refractive power that faces the thing side in the face of concavo-convex the 3rd lens G23 with negative refractive power and its convex surface of thing side with biconvex first lens G21 order, that have positive refractive power from the object side to image side, the biconvex second lens G22 with negative refractive power, its convex surface.The thing side surface of the first lens G21 and the 4th lens G24's is aspheric surface as side surface.
The first lens G21 and the second lens G22 form the cemented lens with composition surface R10, join the first lens G21 thing side concave surface of the second lens G22 to as the side convex surface at this composition surface R10.This convex surface has identical radius-of-curvature with concave surface.
The 3rd lens G23 and the 4th lens G24 form the cemented lens with composition surface R13, join the 3rd lens G23 the thing side convex surface of the 4th lens G24 to as the side concave surface at this composition surface R13.This concave surface has identical radius-of-curvature with convex surface.
The 3rd lens combination GR3 comprises the biconvex lens G31 with positive refractive power.Two surfaces of lens G31 all are aspheric surfaces.
Between the first lens combination GR1 and the second lens combination GR2, arrange aperture diaphragm S (aperture diaphragm surface R8).
Between the 3rd lens combination GR3 and plane of delineation IMG, arrange wave filter FL.
Table 4 shows special value and is applied to lens data according to the numerical example 2 of the zoom lens 2 of second embodiment.
[table 4]
Si Ri Di Ni vi
1 45.000 0.950 1.88300 40.8
2 10.778 3.925
3 95.732 0.900 1.61800 63.4
4 46.766 0.100 1.53420 41.7
5 31.327(ASP) 0.413
6 20.386 2.080 1.84666 23.8
7 64.600 D7
8 Aperture diaphragm 0.500
9 9.481(ASP) 3.700 1.85135 40.1
10 -13.389 0.500 1.63980 34.6
11 10.329 0.512
12 8.945 1.084 2.00069 25.5
13 4.830 2.523 1.69350 53.2
14 9.468(ASP) D14
15 51.001(ASP) 3.214 1.61881 63.9
16 -25.842(ASP) D16
17 INF 1.800 1.51872 64.2
18 INF
In zoom lens 2, the picture side surface (R16) of the thing side surface (R15) of the picture side surface (R14) of the thing side surface (R9) of the picture side surface (R5) of the second lens G12 of the first lens combination GR1, the first lens G21 of the second lens combination GR2, the 4th lens G24 of the second lens combination GR2, the lens G31 of the 3rd lens combination GR3 and the lens G31 of the 3rd lens combination GR3 is an aspheric surface.Table 2 shows asphericity coefficient A4, A6, A8 and A10 and the conic constant K on the 4th, the 6th, the 8th and the 10th rank of the non-spherical surface of numerical example 2.
[table 5]
Si K A4 A6 A8 A10
5 0.00000E+00 -5.20571E-05 -4.43073E-07 3.52326E-09 -6.13429E-11
9 0.00000E+00 -7.83861E-05 -9.26710E-07 -3.54268E-08 4.58833E-10
14 0.00000E+00 3.32744E-04 6.93988E-06 -4.19631E-07 6.01372E-09
15 0.00000E+00 4.36838E-06 -2.98027E-08 -2.62534E-09 0
16 0.00000E+00 5.91910E-05 -8.95904E-07 6.71784E-09 -4.04600E-11
In zoom lens 2, wide-angle side and dolly-out, dolly-back the end between image zoom during, surface distance D14 between the surface distance D7 between the first lens combination GR1 and the second lens combination GR2, the second lens combination GR2 and the 3rd lens combination GR3 and the surface distance D16 between the 3rd lens combination GR3 and the wave filter FL are variablees.Table 6 shows in numerical example 2 variable distance at the surface distance of wide-angle side (focal distance f=10.66), middle focal length (focal distance f=17.95) and the end of dolly-out,ing dolly-back (focal distance f=30.63) with f-number Fno and half angle of view ω.
[table 6]
Fno 2.88 3.9 5.5
f 10.66 17.95 30.63
ω 38.19 24.01 14.56
D7 22.331 9.736 2.600
D14 7.645 16.612 29.375
D16 5.214 3.955 3.094
Fig. 6 shows aberration figure at infinity according to numerical example 2 to Fig. 8.Fig. 6 is shown in the aberration figure of wide-angle side (focal distance f=10.66).Fig. 7 is shown in the aberration figure of middle focal length (focal distance f=17.95).Fig. 8 is shown in the aberration figure of the end of dolly-out,ing dolly-back (focal distance f=30.63).
In the spherical aberration figure of Fig. 8, solid line is illustrated in the d line, and (wavelength: value 587.6nm), dotted line are illustrated in the value of c line (wavelength 656.3nm), and dot-and-dash line is illustrated in g line (wavelength: value 435.8nm) at Fig. 6.In the astigmatism aberration figure of Fig. 8, solid line is illustrated in the value on sagittal image plane, and dotted line is illustrated in the value of the meridian plane of delineation at Fig. 6.
In aberration figure, find the imaging performance of in numerical example 2, suitably proofreading and correct aberration and providing.
Fig. 9 diagram is according to the lens configuration of the zoom lens 3 of third embodiment of the invention;
As shown in Figure 9, the zoom lens 3 of the 3rd embodiment comprise seven lens.
Zoom lens 3 comprise with first lens combination GR1 order, that have negative refractive power from the thing example to picture example, have the second lens combination GR3 of positive refractive power and have the 3rd lens combination GR3 of positive refractive power.
In zoom lens 3, during the image zoom wide-angle side and dolly-out, dolly-back the end between move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction.For example, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 reduces and make the space length between the second lens combination GR2 and the 3rd lens combination GR3 increase.On the contrary, during holding the image zoom of wide-angle side from dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 increases and makes the space length between the second lens combination GR2 and the 3rd lens combination GR3 reduce.
The first lens combination GR1 comprise with from the object side to image side order, its convex surface is in the face of the concavo-convex compound aspheric surface first lens G11 with negative refractive power of thing side and its convex surface concavo-convex second lens G12 with positive refractive power in the face of the thing side.The first lens G11's is aspheric surface as side surface.
The second lens combination GR2 comprises concavo-convex the 4th lens G24 with positive refractive power that faces the thing side in the face of concavo-convex the 3rd lens G23 with negative refractive power and its convex surface of thing side with biconvex first lens G21 order, that have positive refractive power from the object side to image side, the biconvex second lens G22 with negative refractive power, its convex surface.The thing side surface of the first lens G21 and the 4th lens G24's is aspheric surface as side surface.
The first lens G21 and the second lens G22 form the cemented lens with composition surface R8, join the first lens G21 thing side concave surface of the second lens G22 to as the side convex surface at this composition surface R8.This convex surface has identical radius-of-curvature with concave surface.
The 3rd lens G23 and the 4th lens G24 form the cemented lens with composition surface R11, join the 3rd lens G23 the thing side convex surface of the 4th lens G24 to as the side concave surface at this composition surface R11.This concave surface has identical radius-of-curvature with convex surface.
The 3rd lens combination GR3 comprises the biconvex lens G31 with positive refractive power.Two surfaces of lens G31 all are aspheric surfaces.
Between the first lens combination GR1 and the second lens combination GR2, arrange aperture diaphragm S (aperture diaphragm surface R6).
Between the 3rd lens combination GR3 and plane of delineation IMG, arrange wave filter FL.
Table 7 shows special value and is applied to lens data according to the numerical example 3 of the zoom lens 3 of the 3rd embodiment.
[table 7]
Si Ri Di Ni vi
1 245.177 0.950 1.88830 40.8
2 12.180 0.100 1.53420 41.7
3 10.537(ASP) 3.630
4 18.609 3.000 1.84666 23.8
5 53.037 D5
6 Aperture diaphragm 0.500
7 9.385(ASP) 3.617 1.85135 40.1
8 -12.166 0.636 1.63980 34.6
9 11.213 0.474
10 9.780 1.238 2.00069 25.5
11 4.830 2.135 1.69350 53.2
12 9.439(ASP) D13
13 39.886(ASP) 3.360 1.69350 53.2
14 -30.752(ASP) D15
15 INF 1.800 1.51872 64.2
16 INF
In zoom lens 3, the picture side surface (R14) of the thing side surface (R13) of the picture side surface (R12) of the thing side surface (R7) of the picture side surface (R3) of the first lens G11 of the first lens combination GR1, the first lens G21 of the second lens combination GR2, the 4th lens G24 of the second lens combination GR2, the lens G31 of the 3rd lens combination GR3 and the lens G31 of the 3rd lens combination GR3 is an aspheric surface.Table 8 shows asphericity coefficient A4, A6, A8 and the A10 on the 4th, the 6th, the 8th and the 10th rank of the non-spherical surface of numerical example 3 with conic constant K.
[table 8]
Si K A4 A6 A8 A10
3 0.00000E+00 -1.20163E-04 -2.68470E-07 -2.92205E-09 -5.80228E-11
7 0.00000E+00 -1.03215E-04 -4.05742E-07 -8.95031E-08 1.77523E-09
12 0.00000E+00 2.76128E-04 1.26262E-05 -1.12894E-06 3.27515E-08
13 0.00000E+00 7.91571E-05 -1.51823E-07 -3.56747E-09 -1.73138E-11
14 0.00000E+00 1.60709E-04 -9.84738E-07 -3.08422E-09 1.65006E-12
In zoom lens 3, wide-angle side and dolly-out, dolly-back the end between image zoom during, surface distance D12 between the surface distance D5 between the first lens combination GR1 and the second lens combination GR2, the second lens combination GR2 and the 3rd lens combination GR3 and the surface distance D14 between the 3rd lens combination GR3 and the wave filter FL are variablees.Table 9 shows the variable distance at the surface distance of wide-angle side (focal distance f=10.67), middle focal length (focal distance f=18.17) and the end of dolly-out,ing dolly-back (focal distance f=30.73) in numerical example 3 with f-number Fno and half angle of view ω.
[table 9]
Fno 2.88 3.88 5.55
f 10.67 18.17 30.73
ω 38.26 23.71 14.45
D5 20.035 8.568 2.000
D12 7.244 15.961 29.162
D14 5.200 4.571 3.192
Figure 10 shows aberration figure at infinity according to numerical example 3 to Figure 12.Figure 10 is shown in the aberration figure of wide-angle side (focal distance f=10.67).Figure 11 is shown in the aberration figure of middle focal length (focal distance f=18.17).Figure 12 is shown in the aberration figure of the end of dolly-out,ing dolly-back (focal distance f=30.73).
In the spherical aberration figure of Figure 12, solid line is illustrated in the d line, and (wavelength: value 587.6nm), dotted line are illustrated in the value of c line (wavelength 656.3nm), and dot-and-dash line is illustrated in g line (wavelength: value 435.8nm) at Figure 10.In the astigmatism aberration figure of Figure 12, solid line is illustrated in the value on sagittal image plane, and dotted line is illustrated in the value of the meridian plane of delineation at Figure 10.
In aberration figure, find the imaging performance of in numerical example 3, suitably proofreading and correct aberration and providing.
Figure 13 diagram is according to the lens configuration of the zoom lens 4 of fourth embodiment of the invention.
As shown in figure 13, the zoom lens 4 of the 4th embodiment comprise eight lens.
Zoom lens 4 comprise with from the object side to image side first lens combination GR1 order, that have negative refractive power, have the second lens combination GR2 of positive refractive power and have the 3rd lens combination GR3 of positive refractive power.
In zoom lens 4, during the image zoom wide-angle side and dolly-out, dolly-back the end between move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction.For example, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 reduces and make the space length between the second lens combination GR2 and the 3rd lens combination GR3 increase.On the contrary, during holding the image zoom of wide-angle side from dolly-out,ing dolly-back, move the first lens combination GR1, the second lens combination GR2 and the 3rd lens combination GR3 with optical axis direction, so that the space length between the first lens combination GR1 and the second lens combination GR2 increases and makes the space length between the second lens combination GR2 and the 3rd lens combination GR3 reduce.
The first lens combination GR1 comprise with from the object side to image side order, its convex surface in the face of the concavo-convex first lens G11 with negative refractive power of thing side, its convex surface in the face of the concavo-convex compound aspheric surface second lens G12 with negative refractive power of thing side and its convex surface concavo-convex the 3rd lens G13 with positive refractive power in the face of the thing side.The second lens G12's is aspheric surface as side surface.
The second lens combination GR2 comprises concavo-convex the 4th lens G24 with positive refractive power that faces the thing side in the face of concavo-convex the 3rd lens G23 with negative refractive power and its convex surface of thing side with biconvex first lens G21 order, that have positive refractive power from the object side to image side, the biconvex second lens G22 with negative refractive power, its convex surface.The thing side surface of the first lens G21 and the 4th lens G24's is aspheric surface as side surface.
The 3rd lens G23 and the 4th lens G24 form the cemented lens with composition surface R14, join the 3rd lens G23 the thing side convex surface of the 4th lens G24 to as the side concave surface at this composition surface R14.This concave surface has identical radius-of-curvature with convex surface.
The 3rd lens combination GR3 comprises the biconvex lens G31 with positive refractive power.Two surfaces of lens G31 all are aspheric surfaces.
Between the first lens combination GR1 and the second lens combination GR2, arrange aperture diaphragm S (aperture diaphragm surface R8).
Between the 3rd lens combination GR3 and plane of delineation IMG, arrange wave filter FL.
Table 10 shows special value and is applied to lens data according to the numerical example 4 of the zoom lens 4 of the 4th embodiment.
[table 10]
Si Ri Di Ni vi
1 58.332 0.950 1.88830 40.8
2 10.997 4.007
3 164.246 1.000 1.61800 63.4
4 91.238 0.100 1.53420 41.7
5 43.404(ASP) 0.320
6 25.503 2.034 1.84666 23.8
7 149.040 D7
8 Aperture diaphragm 0.500
9 9.196(ASP) 3.345 1.83944 42.7
10 -25.064 0.300
11 -20.983 0.453 1.63980 34.6
12 10.501 0.408
13 8.812 0.794 2.00069 25.5
14 4.830 3.200 1.69350 53.2
15 10.311(ASP) D15
16 49.670(ASP) 2.989 1.58547 59.5
17 -27.741(ASP) D17
18 INF 1.800 1.51872 64.2
19 INF
In zoom lens 4, the picture side surface (R17) of the thing side surface (R16) of the picture side surface (R15) of the thing side surface (R9) of the picture side surface (R5) of the second lens G12 of the first lens combination GR1, the first lens G21 of the second lens combination GR2, the 4th lens G24 of the second lens combination GR2, the lens G31 of the 3rd lens combination GR3 and the lens G31 of the 3rd lens combination GR3 is an aspheric surface.Table 11 shows asphericity coefficient A4, A6, A8 and A10 and the conic constant K on the 4th, the 6th, the 8th and the 10th rank of the non-spherical surface of numerical example 4.
[table 11]
Si K A4 A6 A8 A10
5 0.00000E+00 -6.13061E-05 -2.90090E-07 1.57087E-09 -4.63598E-11
9 0.00000E+00 -3.63853E-05 -4.02378E-07 -3.26016E-08 6.80087E-10
15 0.00000E+00 4.29632E-04 2.55415E-06 1.63782E-07 -4.92902E-09
16 0.00000E+00 5.37906E-05 -3.64063E-07 -7.30974E-10 -2.27081E-11
17 0.00000E+00 1.32849E-04 -1.34487E-06 5.87006E-09 -4.26151E-11
In zoom lens 4, wide-angle side and dolly-out, dolly-back the end between image zoom during, surface distance D15 between the surface distance D7 between the first lens combination GR1 and the second lens combination GR2, the second lens combination GR2 and the 3rd lens combination GR3 and the surface distance D17 between the 3rd lens combination GR3 and the wave filter FL are variablees.Table 12 shows in numerical example 4 variable distance at the surface distance of wide-angle side (focal distance f=10.67), middle focal length (focal distance f=17.87) and the end of dolly-out,ing dolly-back (focal distance f=30.72) with f-number Fno and half angle of view ω.
[table 12]
Fno 2.90 3.87 5.60
f 10.67 17.87 30.72
ω 38.20 23.99 14.39
D7 20.382 9.281 2.600
D15 7.261 15.657 29.349
D17 5.427 4.697 2.941
Figure 14 shows aberration figure at infinity according to numerical example 4 to Figure 16.Figure 14 is shown in the aberration figure of wide-angle side (focal distance f=10.67).Figure 15 is shown in the aberration figure of middle focal length (focal distance f=17.87).Figure 16 is shown in the aberration figure of the end of dolly-out,ing dolly-back (focal distance f=30.72).
In the spherical aberration figure of Figure 16, solid line is illustrated in the d line, and (wavelength: value 587.6nm), dotted line are illustrated in the value of c line (wavelength 656.3nm), and dot-and-dash line is illustrated in g line (wavelength: value 435.8nm) at Figure 14.In the astigmatism aberration figure of Figure 16, solid line is illustrated in the value on sagittal image plane, and dotted line is illustrated in the value of the meridian plane of delineation at Figure 14.
In aberration figure, find the imaging performance of in numerical example 4, suitably having proofreaied and correct aberration and providing.
Table 13 shows the value that the conditional expression (1) that is respectively applied for zoom lens 1,2,3 and 4 arrives (3).Specifically, described value comprises f2, f2R and the f2/f2R of conditional expression (1), L2, LT and the L2/LT of conditional expression (2), and v24, v23 and the v23-v24 of conditional expression (3).
[table 13]
Figure A20091020281900211
As shown in table 13, zoom lens 1,2,3 and 4 satisfy condition expression formula (1) to (3).
Next, image pick up equipment is according to an embodiment of the invention described.
The image pick up equipment of this embodiment comprises zoom lens and will be converted to the image pickup device of electric signal by the optical imagery that zoom lens form.
The zoom lens that provide in image pick up equipment comprise with from the object side to image side first lens combination order, that have negative refractive power, have second lens combination of positive refractive power and have the 3rd lens combination of positive refractive power.During the image zoom in wide-angle side with dolly-out, dolly-back and move first, second and the 3rd lens combination with optical axis direction between the end.
For example, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move first lens combination with optical axis direction, second lens combination is moved to the thing side, and the 3rd lens combination is moved to the picture side, so that the space length between first and second lens combination reduces and make the space length between the second and the 3rd lens combination increase.
In the zoom lens that in the image pick up equipment of embodiments of the invention, provide, second lens combination comprise with from the object side to image side first lens order, that have positive refractive power, have negative refractive power second lens, have the 3rd lens of negative refractive power and have the 4th lens of positive refractive power.Engage third and fourth lens, thus serve as cemented lens.
In the zoom lens that provide in the image pick up equipment of this embodiment, second lens combination comprises four lens, and provides cemented lens by third and fourth lens.That is to say that the number of lens is very little, and two lens are as cemented lens.Therefore, can reduce total optical path.
The zoom lens that provide in the image pick up equipment of this embodiment are configured to and satisfy following conditional expression (1) and (2):
(1)-0.5<f2/f2R<0 and
(2)0.09<L2/LT<0.19,
Wherein f2 is the focal length of second lens combination, and f2R is the combined focal length of cemented lens that comprises third and fourth lens of second lens combination, and L2 is the total length about the optical axis of second lens combination, and LT is at the total optical path of end of dolly-out,ing dolly-back.
Conditional expression (1) is determined the focal length and the ratio of the 3rd lens with negative refractive power that comprise second lens combination with the focal length of the cemented lens of the 4th lens with positive refractive power of second lens combination.
If the value of conditional expression (1) is higher than the upper limit, then the position of the basic point of second lens becomes too near the picture side.It is big that total optical path may become.This may be the bottleneck that size reduces.
On the contrary, if the value of conditional expression (1) is lower than lower limit, comprise that then the refractive power variable of cemented lens of the 3rd lens of second lens combination and the 4th lens is too much.Therefore, the combination refractive power of first and second lens of second lens also becomes big.Therefore, the sensitivity of the excentricity of first and second lens of the cemented lens and second lens combination becomes excessive.It is difficult that manufacturing may become.
If the value of conditional expression (1) is lower than lower limit, specifically, the distance between the exit pupil position and the plane of delineation diminishes in wide-angle side, and becomes greatly from the incident angle of Axial Bundle about the plane of delineation.Therefore, increase shade.
Conditional expression (2) is determined the total length of second lens combination.
For reducing the total optical path of whole zoom-lens system when compressing (contraction), expectation reduces the total length of second lens combination.Yet if the value of conditional expression (2) is lower than lower limit, the total length of second lens combination becomes too small, and the sensitivity of the excentricity error of second lens combination uprises.Therefore, must carry out assembling with very high precision.
On the contrary, if the value of conditional expression (2) is higher than the upper limit, then the total length of second lens combination becomes excessive, and is difficult to promote reducing of total optical path under the compressive state.
Therefore, when the image pick up equipment of this embodiment satisfies condition expression formula (1) and (2), can reduce total optical path, and can promote reducing of size thus.And, can boost productivity by the sensitivity that reduces excentricity, high optical property is provided simultaneously.
Figure 17 illustrates the conduct digital camera of image pick up equipment according to an embodiment of the invention briefly.
Image pick up equipment (digital camera) 100 comprises the camera module 10 with image pickup function, execution is such as the camera signal processor 20 of the signal Processing of analog to digital conversion of the picture signal of catching and so on, the record of carries out image signal and the image processor of reproduction processes 30, the LCD (LCD) 40 of the image that demonstration is caught etc., the carries out image signal is to the reader/writer that reads and write (R/W) 50 of storage card 1000, the CPU (central processing unit) (CPU) 60 of control entire image pick device, the user is with its lens driving governor 80 of carrying out the input block 70 of scheduled operation and being controlled at the driving of the lens of arranging in the camera module 10.
Camera module 10 comprises zoom lens 11 ( zoom lens 1,2,3 or 4 that the present invention is applied to) and such as the image pickup device 12 of charge-coupled device (CCD) or complementary metal oxide semiconductor (CMOS) (CMOS) and so on.
For example, camera signal processor 20 carry out conversion from the signal of image pickup device 12 outputs to digital signal, squelch, image quality correction, to the conversion of luminance signal and colour difference signal.
Image processor 30 comes the compressed/encoded of carries out image signal and decompressed/decoded based on the predetermined image data layout and such as the conversion of the data requirement of resolution and so on.
LCD 40 has the mode of operation to input block 70 explicit users, and such as the function of the various data of image of catching and so on.
R/W 50 carries out by image processor 30 image encoded data and writes and be stored in reading of view data in the storage card 1000 to storage card 1000.
CPU 60 is as the processor controls that the circuit module that provides in the image pick up equipment 100 is provided.CPU 60 based on, for example, from the command input signals control circuit module of input block 70.
For example, input block 70 is the selector switch that are used for the shutter release button of shutter operation and are used for the selection of operator scheme.Input block 70 outputs to CPU60 according to user's operation with command input signals.
Lens driving governor 80 is based on the (not shown) such as motor that come the lens of controlling and driving zoom lens 11 from the control signal of CPU 60.
For example, storage card 1000 is the semiconductor memories that removably are attached to the groove that is connected with R/W 50.
The operation of following description image pick up equipment 100.
In the holding state of taking, under the control of CPU 60, will output to LCD 40 via camera signal processor 20 in the picture signal that camera module 10 is caught.Display image signals is passed through image (camera through image) as camera on LCD 40.When input block 70 input is used for the command input signals of image zoom, CPU 60 outputs to lens driving governor 80 with control signal.Under the control of lens driving governor 80, the predetermined lens of mobile zoom lens 11.
When by the time from the shutter (not shown) of the command input signals operate camera module of input block 70, the picture signal of being caught is outputed to image processor 30 from camera signal processor 20, compression and the coding picture signal of being caught, and be converted into the numerical data of tentation data form.Institute's data converted is outputed to R/W 50, and write in the storage card 1000.
For example, when partly pressing or pressing fully the shutter release button of input block 70, carry out focusing to write down (shooting).During focusing on, lens driving governor 80 moves the predetermined lens of zoom lens 11 based on the control signal from CPU 60.
For reproduction is stored in view data in the storage card 1000, by R/W 50 according to the operation of input block 70 is read the predetermined image data from storage card 1000.Image processor 30 is carried out decompressed/decoded, and the picture signal of reproducing is outputed to the image of LCD 40 with display reproduction.
Though image pick up equipment is applied to digital camera in the above-described embodiments, but the application of image pick up equipment is not limited to digital camera, and can be applied to Digital Video, perhaps such as mobile phone, perhaps has the camera part of digital input-output apparatus of the PDA(Personal Digital Assistant) and so on of camera with camera.
The shape of the various piece of Miao Shuing and numerical value only are the examples of realization of the present invention in an embodiment.
The application comprise with on the May 26th, 2008 of relevant theme of disclosed theme in the Japanese priority patent application JP 2008-137106 that Jap.P. office submits to, its full content is included in this by reference fully.
Those skilled in the art should understand that according to designing requirement and other factors and can carry out various modifications, combination, part combination and change are as long as they are within appended claim or its equivalent scope.

Claims (4)

1. zoom lens comprise:
With from the object side to image side first lens combination order, that have negative refractive power, have second lens combination of positive refractive power and have the 3rd lens combination of positive refractive power,
Wherein, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move described first lens combination with optical axis direction, and described second lens combination is moved to described thing side, so that the space length between described first and second lens combination reduces and make the space length between the described second and the 3rd lens combination increase
Wherein, described second lens combination comprise with from described thing side to described first lens order, that have positive refractive power as side, have negative refractive power second lens, have the 3rd lens of negative refractive power and have the 4th lens of positive refractive power,
Wherein, described third and fourth lens of described second lens combination be engaged with each other with as cemented lens and
Wherein, described zoom lens are configured to and satisfy following conditional expression (1) and (2):
(1)-0.5<f2/f2R<0 and
(2)0.09<L2/LT<0.19,
Wherein f2 is the focal length of described second lens combination, f2R is the combined focal length of described cemented lens that comprises described third and fourth lens of described second lens combination, L2 is the total length about the optical axis of described second lens combination, and LT is the total optical path at the described end of dolly-out,ing dolly-back.
2. zoom lens as claimed in claim 1, wherein, described zoom lens are configured to and satisfy following conditional expression (3):
(3)v24-v23>20,
Wherein, v24 is the Abbe number of described the 4th lens of described second lens combination, and v23 is the Abbe number of described the 3rd lens of described second lens combination.
3. zoom lens as claimed in claim 1 or 2, wherein, described the 4th lens of described second lens combination be aspheric surface as side surface.
4. image pick up equipment comprises:
Zoom lens; With
Image pickup device, it will be converted to electric signal by the optical imagery that described zoom lens form,
Wherein, described zoom lens comprise,
With from the object side to image side first lens combination order, that have negative refractive power, have second lens combination of positive refractive power and have the 3rd lens combination of positive refractive power,
Wherein, during convergent-divergent from wide-angle side to the end of dolly-out,ing dolly-back, move described first lens combination with optical axis direction, and described second lens combination is moved to described thing side, so that the space length between described first and second lens combination reduces and make the space length between the described second and the 3rd lens combination increase
Wherein, described second lens combination comprise with from described thing side to described first lens order, that have positive refractive power as side, have negative refractive power second lens, have the 3rd lens of negative refractive power and have the 4th lens of positive refractive power.
Wherein, described third and fourth lens of described second lens combination be engaged with each other with as cemented lens and
Wherein, described zoom lens are configured to and satisfy following conditional expression (1) and (2):
(1)-0.5<f2/f2R<0 and
(2)0.09<L2/LT<0.19,
Wherein f2 is the focal length of described second lens combination, f2R is the combined focal length of described cemented lens that comprises described third and fourth lens of described second lens combination, L2 is the total length about the optical axis of described second lens combination, and LT is the total optical path at the described end of dolly-out,ing dolly-back.
CN2009102028195A 2008-05-26 2009-05-26 Zoom lens and image pickup appartus Expired - Fee Related CN101592775B (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
JP2008137106A JP5141375B2 (en) 2008-05-26 2008-05-26 Zoom lens and imaging device
JP137106/08 2008-05-26

Publications (2)

Publication Number Publication Date
CN101592775A true CN101592775A (en) 2009-12-02
CN101592775B CN101592775B (en) 2011-01-05

Family

ID=41341905

Family Applications (1)

Application Number Title Priority Date Filing Date
CN2009102028195A Expired - Fee Related CN101592775B (en) 2008-05-26 2009-05-26 Zoom lens and image pickup appartus

Country Status (3)

Country Link
US (1) US7830615B2 (en)
JP (1) JP5141375B2 (en)
CN (1) CN101592775B (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113448179A (en) * 2021-07-02 2021-09-28 浙江大学 Nano laser direct writing objective lens

Families Citing this family (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP5044356B2 (en) * 2007-10-12 2012-10-10 日東光学株式会社 Zoom lens system
JP2010122458A (en) * 2008-11-19 2010-06-03 Sony Corp Zoom lens and image pickup device
US8503092B2 (en) 2010-08-31 2013-08-06 Nikon Corporation Zoom lens, optical apparatus and method of manufacturing zoom lens
JP5110451B2 (en) 2010-08-31 2012-12-26 株式会社ニコン Zoom lens, optical device, and method of manufacturing zoom lens
WO2014007298A1 (en) * 2012-07-03 2014-01-09 株式会社タムロン Zoom lens
KR101622160B1 (en) 2014-06-09 2016-05-19 주식회사 소모비전 Wide field lens
JP6555976B2 (en) 2015-08-10 2019-08-07 キヤノン株式会社 Zoom lens and imaging apparatus using the same
CN115236843B (en) * 2022-08-09 2024-01-30 舜宇光学(中山)有限公司 Zoom lens

Family Cites Families (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP3619117B2 (en) * 2000-04-14 2005-02-09 キヤノン株式会社 Zoom lens and optical apparatus using the same
US6671103B2 (en) * 2000-12-27 2003-12-30 Canon Kabushiki Kaisha Zoom lens and optical apparatus using the same
JP3548537B2 (en) 2001-02-22 2004-07-28 キヤノン株式会社 Zoom lens and optical device using the same
JP3599689B2 (en) * 2001-08-03 2004-12-08 キヤノン株式会社 Zoom lens
JP4076332B2 (en) * 2001-10-04 2008-04-16 オリンパス株式会社 Electronic imaging device
JP4271436B2 (en) 2002-12-10 2009-06-03 パナソニック株式会社 Zoom lens and electronic still camera
JP2006039182A (en) * 2004-07-27 2006-02-09 Konica Minolta Photo Imaging Inc Imaging apparatus
CN100406953C (en) * 2005-09-06 2008-07-30 佳能株式会社 Zoom lens and image pickup apparatus including the same
JP4902179B2 (en) * 2005-11-29 2012-03-21 キヤノン株式会社 Zoom lens and imaging apparatus having the same
JP2007212777A (en) 2006-02-09 2007-08-23 Nikon Corp Zoom lens
JP4950608B2 (en) * 2006-09-13 2012-06-13 キヤノン株式会社 Zoom lens and imaging apparatus having the same

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113448179A (en) * 2021-07-02 2021-09-28 浙江大学 Nano laser direct writing objective lens
CN113448179B (en) * 2021-07-02 2022-05-24 浙江大学 Nano laser direct writing objective lens

Also Published As

Publication number Publication date
JP5141375B2 (en) 2013-02-13
US20090290231A1 (en) 2009-11-26
US7830615B2 (en) 2010-11-09
JP2009282466A (en) 2009-12-03
CN101592775B (en) 2011-01-05

Similar Documents

Publication Publication Date Title
CN101592775B (en) Zoom lens and image pickup appartus
US8520318B2 (en) Zoom lens and imaging apparatus
US7952811B2 (en) Zoom lens and image pickup device
JP4853764B2 (en) Zoom lens
CN101794013B (en) Zoom lens and image capture apparatus
CN101373263B (en) Zoom lens and image-capture device
JP5029185B2 (en) Variable magnification optical system, imaging device, and digital device
US9817218B2 (en) Zoom lens and imaging apparatus
CN102103253A (en) Zoom lens and image pickup apparatus
CN101285929A (en) Zoom lens and imaging device
CN101872061B (en) Zoom lens and imaging apparatus
CN101738711B (en) Zoom lens and image pickup device
JP2011022191A (en) Zoom lens and imaging apparatus
CN102645735A (en) Zoom lens and imaging apparatus
JP4697556B2 (en) Zoom lens and imaging device
CN103513408A (en) Zoom lens and imaging apparatus
JP2009217167A (en) Zoom optical system and imaging apparatus
CN101806954A (en) Zoom lens and image pick-up device
US7486327B2 (en) Image-taking optical system
US8760770B2 (en) Zoom lens and imaging apparatus
US8031256B2 (en) Zoom lens and image pickup device
CN101533149B (en) Zoom lens and image pickup apparatus
US8284499B2 (en) Zoom lens and imaging apparatus
JP2012252278A (en) Zoom lens and imaging apparatus

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20110105

Termination date: 20150526

EXPY Termination of patent right or utility model